Rinsing device for personal hygiene

ABSTRACT

A nozzle assembly for coupling with the outlet of a rinsing device. The assembly includes a two-part nozzle holder, with one part having a pair of diametrically opposite grooves. Each of the grooves has one groove section inclined to the axis of the nozzle holder and a second groove section which merges into the first. The second section is oriented perpendicular to the axis of the nozzle holder. The other part of the nozzle holder includes a pair of projections deposed in the grooves. Rotation of one part of the holder with respect to the other causes a valve assembly to open and close. The valve assembly includes an internal pin within the nozzle assembly. The pin has a rounded head and forms the closing member. It is situated within a flow passage defined by a bushing having an inner sleeve. Axial grooves may be provided to facilitate assembly of the two-part nozzle.

CROSS REFERENCE TO RELATED APPLICATION

This application is divisional application of Ser. No. 761,269, filedJan. 21, 1977.

BACKGROUND OF THE INVENTION

Known rinsing devices which are generally intended for connection to thewater tap of a water pipe have the disadvantage that the amount of wateremerging from the spray nozzle and available for the liquid treatment isreduced by that proportion which is needed to drive the turbine andwhich constantly emerges from the turbine jet openings and throughcorresponding discharge openings. As a result, the liquid pulsesproduced, even with a comparatively high tap water pressure are not sopowerful and sharp as is desirable for effective treatment. In addition,in the known rinsing devices working with turbines, the turbine speedincreases substantially linearly with the pressure of the tap water.Therefore, if the user increases the water pressure, that is to sayturns the water tap on further then the pulse repetition frequency ofthe pulsating jet of liquid produced also increases in an unfavorablemanner.

SUMMARY OF THE INVENTION

The principal object of the invention is to provide a rinsing device ofthe kind described which is easily connected to a water pipe, so thatthe amount of water available for liquid treatment is increased and apulsating liquid jet is produced with more powerful and sharplypronounced pulses, as a result of which the effectiveness of the liquidmassage, rinsing and/or cleansing is increased.

Toward this end, the rinsing device according to this invention includesa further rotary valve disposed in the conduit leading from thepressure-water passage to the jet opening. The rotating element of thisvalve is rapidly connected to the rotating part of the first rotatingvalve and which is adapted to block this conduit intermittently eachtime, at least approximately during that interval of time when the firstrotary valve is passing through its open position.

As a result, during the period that the outlet is open, the entireamount of water supplied is available to produce the liquid pulses, thepower of which is thus increased accordingly; this effect of producingsharper liquid pulses is enhanced by the repeated backing-up effect inthe pressure-water passage as a result of the blocking of the turbinefeed. In this manner, the rinsing device according to the inventionpermits a more effective liquid massage and rinsing than deviceshitherto known and, particularly in the case of a mouthwashing device, aparticularly satisfatory massage of the gums and an effective cleaningand rinsing of the teeth and the gaps therebetween is attained.

In addition, it has been found that with the rinsing device according tothe invention, the turbine speed advantageously only increases with thewater pressure up to a specific, comparatively low pressure of the feedwater, but then remains substantially constant as the water pressurerises further. In an embodiment of the rinsing device according to theinvention, the turbine speed rose with rinsing water pressure only up toa pressure of about 2-2.5 bar up to about 2,500 r.p.m. and then remainedapproximately constant as the water pressure rose further, beingincreased to about 10 bar, that is to say about 10 at. This has thegreat advantage that the pulse repetition frequency of the liquid pulsesremains substantially constant in the range of the pressure generallyused in practice for the liquid treatment. It is believed that thisextremely advantageous effect results essentially from the intermittentfeed of the turbine.

Known rinsing devices equipped with a thrust bearing for the turbinefurther have the disadvantage that this thrust bearing is heavily loadedunder the action of the pressure of the water flowing in the directionof the turbine axis, generally through a hollow turbine shaft, and thecomparatively great friction thus produced has an adverse effect on therunning of the small turbine. In order to largely avoid this problem,the present invention when equipped with a thrust bearing for theturbine, provides the turbine surface which is adjacent to the thrustbearing which preferably consists of a ball and a contact surface forthe ball, is preferably provided with wing-like projections which, onrotation of the turbine, produce a force which counteracts the forceurging the turbine towards the thrust bearing. Furthermore, the turbinewall adjacent to the said bearing can be provided with axial channelsthrough which water jets can pass with a force that also counteracts thefrictional force of the thrust bearing. These axially directed jets havebeen found to function as a sort of velocity regulator which creates abraking effect which contributes to holding constant the speed ofrotation of the turbine. Also the internal pressure is reduced which isalso quite useful.

In a rinsing device according to the invention a nozzle holder isprovided which can be connected to a connecting tube for theinterchangeable attachment of a spray nozzle. The nozzle holder consistsof two coaxial parts which are capable of being turned or screwedthrough a limited angle between two positions. A shut-off valve withinthe holder closes a flow passage in one position and in the otherposition opens it. The screw connection preferably comprises on the onepart diametrically opposite grooves with a groove section orientedobliquely to the axis of the nozzle holder and a peripheral groovesection orientated perpendicular to the axis of the nozzle holder anddefining the closed position, and on the other part projections whichengage in these grooves.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings:

FIG. 1 shows a diagrammatic view of the rinsing device of thisinvention;

FIG. 2 shows a longitudinal axial section through the liquid pulsegenerator;

FIGS. 3a and 3b show cross-sectional views through the two rotaryvalves, namely, through the liquid pulse generator of FIG. 2 at theheight of the outlet (FIG. 3a) and through its turbine (FIG. 3b);

FIGS. 4a and 4b are similar views with the outlet closed and the turbinefeed released;

FIG. 5 shows a perspective view of the side of the turbine adjacent tothe thrust bearing;

FIG. 6 shows a longitudinal section through the nozzle holder withsuperimposed spray nozzle and with the shut-off valve in the closedposition;

FIG. 7 is a similar section with the shut-off valve in the openposition;

FIG. 8 shows a side view of the handle portion of the nozzle holder; and

FIG. 9 shows a plan view of the front end face of the handle portion ofFIG. 8.

DETAILED DESCRIPTION

Referring initially to FIG. 1, the rinsing device of the presentinvention comprises a liquid pulse generator 1, which can be connected,by its inlet socket 2, to any desired source of pressure water,particularly to the tap of a water pipe.

The socket 3 at the outlet of the liquid pulse generator 1 is connectedby a flexible tube 4 to a spray-nozzle holder 5 which has a handleportion and carries an interchangeable spray nozzle with the nozzle tube6 and the nozzle head 7 located at the discharge end.

Referring now to FIG. 2, the liquid pulse generator 1 has a housing body8, which receives at its inlet side an inlet socket 2, held by a lockingsleeve 9 and resilient locking tongues 8a of the housing body 8 which ispressed into corresponding recesses 2a at the periphery of the inletsocket 2. The locking sleeve 9 is held captive by resilient engagementof a radial inwardly extending flange 9a in an annular groove 8b at theperiphery of the housing body 8, but is movable axially between thelocking position shown in FIG. 2 and an unlocking position whichreleases the locking tongues 8a and in which it is displaced upwards incomparison with the position in FIG. 2.

The open side of the housing body 8, remote from the inlet, is coveredby a resiliently coupled cap 10 which is provided with water dischargeopenings 11.

An axial hollow pin 12 is secured at its end 13, in a correspondinglystepped inner wall region 14 of the housing body 8. Pin 12 is surroundedby an internal sleeve 15, forming an annular chamber and carries arotatably mounted turbine shaft 16 with a turbine 17.

An annular ring 22 extends from wall region 14 and about which the inletsocket 2 is mounted. A grating or screen 23 is disposed at the openingof the hollow pin 12 with ring 22. Wall region 14, internal sleeve 15and annular ring 22 are integral parts of the housing body 8. A sealingring 24 is provided in the inlet socket 2 and a further sealing ring 25is provided between the inlet socket 2 and the housing. When the inletsocket 2 is connected to a water pipe, water under pressure flows intothe hollow pin 12, the interior of which forms the pressure-waterpassage.

The turbine 17, which is secured to the turbine shaft 16, is constructedin a manner depicted in FIGS. 2, 3b, 4b and 5. In this connection, theturbine 17 is in the form of a hollow wheel into which the interior ofthe hollow pin 12 leads. The turbine 17 comprises, at its periphery, twodiametrically opposite, tangentially orientated jet openings 18a and18b. For manufacturing reasons, the turbine 17 is composed of twobowl-shaped portions 17a and 17b. The outer wall of the turbine portion17b, comprises a central, hollow cylindrical extension 19 in which thereis a ball 20. The ball 20 can bear against a bearing surface 21 (FIG. 2)which is formed on the inside of the cap 10 in the form of a cylindricalprojection that has a smaller diameter than ball 20. In this manner,ball 20 and bearing surface 21 form a thrust bearing for the turbine 17,when urged towards the cap 10, during operation, under the effect of thewater pressure.

The bearing surface 21 is provided with a small slightly conical recessso as to correctly center the ball 20. When the apparatus is first used,the ball 20 is centered on the bearing surface 21 and bears on thecircular edge of this conical recess. When the apparatus has been usedfor some time, there is a "running-in" effect, in that the circular edgeof the recess is worn away by friction until there is formed a cavityadapted to the curvature of the ball; however, this effect haspractically no disadvantage as centering is still maintained, and thefriction remains constant after "running-in" since the diameter of thecircular bearing face 21, defined by the diameter of the cylindricalprojection, always remains the same.

As shown in FIG. 2, the length of the hollow turbine shaft 16 is sodimensioned in relation to the length of the hollow pin 12 that theturbine 17 together with its shaft 16 has axial clearance.

According to FIGS. 2, 3a and 4a, the peripheral wall of the hollowturbine shaft 16 comprises an aperture 26 which, when the turbine shaftis in the position illustrated in FIGS. 2 and 3a, is in alignment withan opening 27 provided in the wall of the hollow pin 12 and an outlet 28which is provided in the wall of the internal sleeve 15 and which leadsinto the radial outlet socket 3 with the attached tube 4. Therefore, theturbine shaft 16 in conjunction with the opening 27 in the hollow pin12, simultaneously forms the valve body and the aperture 26 forms thevalve opening of a rotary valve. When the turbine is rotating, the shaft16 only permits discharge through the outlet 28 or the outlet socket 3intermittently and so produces a pulsating jet of liquid conveyedthrough the tube 4 to the spray nozzle.

The end of the hollow pin 12 leading into the interior of the turbine 17has, according to FIGS. 2, 3b and 4b a recess 29 at its periphery and issurrounded by an internal, sleeve-shaped wall portion 30 of the turbine17, which is provided with a peripheral opening 31. The arrangement issuch that this opening 31 is always covered by the wall section 32 ofthe hollow pin 12 whenever the aperture 26 in the turbine shaft 16releases the liquid outlet to the spray nozzle; on the other hand, theopening 31 is only in alighment with the recess 29 in the hollow pin 12and therefore only permits a feed of the slide openings 18a and 18b ofthe turbine with pressure water, when the outlet 28 is blocked. Thus,the opening 31 in the turbine 17, in conjunction with the wall section32 of the hollow pin 12, forms the valve opening of a further rotaryvalve, which has a common valve body with the first-mentioned rotaryvalve, namely the turbine shaft, and only adopts its open position whenthe first-mentioned rotary valve is in its closed position. The aperture26 in the turbine shaft 16, the opening 27 in the wall of the hollow pin12 and the recess 29 at the end of the hollow pin extend at leastsubstantially over an arc of a semicircle, while the outlet 28 and theopening 31 in the interior of the turbine 17 occupy a considerablysmaller peripheral region (see FIGS. 3a, 3b, 4a and 4b). In this manner,practically the whole amount of pressure water supplied is available tofeed the spray nozzle whenever the outlet 28 or the outlet socket 3 isopen because the turbine feed is interrupted. In addition, as has beenfound, the intermittent feed of the turbine 17 contributes to the factthat the turbine speed practically no longer rises with a rising waterpressure above a comparatively low water pressure which, in a successfulembodiment was about 2.5 bar, but remains approximately constant and, inthis embodiment was about 2,500 r.p.m. This has the advantage that, withthe water pressures which are generally available and within thepressure ranges generally used by the user, the turbine speed and hencethe pulse repetition frequency of the pulsating jet of liquid producedis at least approximately constant.

The liquid pulse generator 1 is normally connected to the water tap overa wash-basin and then has its axis or its pressure-water passage in avertical position, with the cap 10 facing downwards and situated abovethe drain of the wash-basin. The liquid flowing through thepressure-water passage in the hollow pin 12 and the interior of theturbine 17 emerges from the jet openings 18a and 18b of the turbine 17,as indicated by the arrows F in FIG. 4b. As a result the turbine is setin rotation by reaction. The water emerging from the turbine andreaching the lower region of the housing can run away through thedischarge openings 11 in the cap 10. A pulsating jet of liquid, feedingthe attached spary nozzle, as indicated by the arrow F in FIG. 3a, isproduced in the outlet 28, as described, by the rotating turbine shaft16 together with its aperture 26. In the example shown in FIG. 2, theinternal diameter of the hollow pin 12 and hence the cross-section ofthe pressure-water passage becomes narrower immediately behind theopening 27, as a result of which a certain damming up of liquid isproduced at this point, through which the amount of liquid emerging fromthe outlet 28 is increased.

In order to reduce the severe friction occurring under the action of thecomparatively high liquid pressure, between the ball 20 and the bearingsurface 21, and so to relieve the thrust bearing of the turbine, twowing-like extensions 33a (FIG. 5) are formed on the outer face of theturbine 17 adjacent to the thrust bearing, namely, on the outer wall ofthe turbine portion 17b. Accordingly, upon rotation of the turbine, anaxial force is produced which tends to lift the turbine from the bearingsurface 21. According to FIG. 5 the two wing-like extensions 33a areformed diametrically opposite at both sides of the hollow cylindricalprojection 19. These extensions 33a in the form of radial ribs have atriangular cross-section, the surfaces which face in the direction ofrotation of the turbine and in the direction of the arrow of FIG. 5,being inclined obliquely to the plane of rotation of the turbine.

In addition, the same turbine wall is provided withdiametrically-opposed axial channels 33 through which a small quantityof water escapes. Tests have shown that these weak jets of water, whichissue axially with a given force from the lower face of the turbine, actas a kind of speed regulator by providing a braking effect so that overand above a given pressure of water supply, the holding constant of thespeed of rotation of the turbine is further improved.

As a result of both the wing-like extensions 33a and the axial jetsthrough the axial channels 33, the thrust-bearing friction is reducedand the effect is achieved that the turbine runs more easily and alsomore uniformly than in devices of this kind hitherto known.

FIGS. 6-9 show the mounting of the nozzle holder 5 for the spray nozzlewhich can be attached interchangeably. This nozzle holder is constructedin two parts and consists of an elongated hollow handle portion 34 and abushing 35 which is mounted on its front end for screwing within alimited angle and in which the spray nozzle 6, 7 can be inserted. Therotation of tube 6 relative to the handle portion 34 causes the shuttingoff or the opening of a shut-off valve in the nozzle holder between endpositions.

The rear end of the hollow handle portion 34 is connected to theflexible tube 4 by means of a connecting piece 36. In the front region,the handle portion 34 comprises a central pin 38 which is connected tothe peripheral wall by radial ribs 37 (FIG. 9) and forms, with its head39, the closing member of the shut-off valve. The front region of theperipheral wall of the handle portion 34 has, at its outside, twodiametrically opposite angled grooves 40 (FIG. 8) with each comprising agroove section 40a which is orientated obliquely to the axis of thehandle portion and forms part of a screw thread and which merges into agroove secton 40b extending substantially perpendicular to the axis ofthe handle portion. The end of the oblique groove section 40a of each ofthe grooves 40, adjacent to the front of the handle portion 34, leadsinto an axial portion 41 and the depth of which is somewhat less thanthe depth of the angled grooves 40. For manufacturing reasons, thehandle portion 34 is preferably moulded in two parts: an outer tubularpart which forms the gripping part of the handle and in which iselastically clip-fitted an inner part comprising the valve elements andthe screw-thread-shaped groove 40.

The bushing 35 consists of an inner sleeve 42 and an outer sleeve 44which together are made integral and are connected to one another, inthe front region, by a radial wall 47 which comprises at least twoopenings for manufacturing reasons. The inner sleeve 42 receives thetube 6 of the spray nozzel 6, 7 and comprises, at its rear, the flowpassage 43 of said shut-off valve, which cooperates with the closingmember 39 of the handle portion 34. The outer sleeve 44 has, at itsinterior, two diametrically opposite projections 45 which are disposedin the grooves 40, and which are of a width approximating that of thegrooves 40. The outer periphery of the outer sleeve 44 is provided witha knurling 46.

The inner sleeve 42 includes at its rear an annular shoulder 48 whichprojects radially inwards and which defines the flow passage 43 of theshut-off valve. This shoulder 48 also forms the seating surface for theclosing member 39 at its rear and terminates in an annular lip 49 at itsfront. The rear end of the tube 6 of the spray nozzle engages in theannular space surrounding this annular lip 49 and, in this manner, canbe inserted tightly in the bushing 35 and held by means of a resilientlyflexible engagement projection 50 which is formed at the inner peripheryof the inner sleeve 42 and engages in a corresponding notch at theperiphery of the nozzle tube 6. The tight connection between bushing 35and handle portion 34 is achieved by means of an annular lip 51 which isformed at the rear end of the internal sleeve 42 of the bushing 35.

By turning the handle portion 34 relatively to the bushing 35, theprojections 45 on the bushing are accordingly shifted into the guidinggrooves 40 in the handle portion 34. In the shut-off positionillustrated in FIG. 6, the closing member 39 blocks the flow passage 43while bearing against the valve seat and the projections 45 on thebushing 35 are inside the peripheral inner groove section 40b. In theopen position illustrated in FIG. 7, the flow passage 43 is open and theprojections 45 are at the front end of the oblique groove section 40a. Areliable and stable closing position of the shut-off valve is achievedby the peripheral inner groove section 40b defining the closed position.As soon as the projections 45 reach the oblique groove section 40a,during rotation into the open position, the shut-off valve automaticallyadopts its open position if the water pressure is sufficiently strong.

In order to assemble the nozzle holder 5 from the two parts 34 and 35,it is sufficient to slide the bushing 35 onto the handle portion 34,with engagement of the projections 45 in the axial grooves 41. Thesliding motion is continued until the projections 45 engage in thegrooves 40 which, as mentioned, have a somewhat greater depth than theaxial grooves 41, so that now the bushing 35 can no longer simply bedetached from the handle portion 34. In order to facilitate this slidingof the bushing 35 onto the handle portion 34 during assembly, the innerfaces of the projections 45 are bevelled relative to the axis of thehandle portion in such a manner that they are inclined outwardly in arearward direction.

Thus, the nozzle holder 5 can be assembled of a suitable plasticsmaterial, very simply and without separate attachment means. The sameapplies to the liquid pulse generator which, with the exception of theball 20 and preferably the turbine shaft 16 and the grating 23, whichconsist of metal, is composed of plastics parts. All the parts of thegenerator are capable of being connected to one another without usingseparate attachment members, either by resilient interengagement or by aforce fit. Thus, the rinsing device according to the invention producessharper liquid pulses with comparatively greater amounts of water whilerelieving the thrust bearing of the turbine but also is of simpleconstruction and easily assembled at reduced costs.

Instead of only one aperture 26 in the turbine shaft 16 and only oneopening 31 in the inner sleeve 30 of the turbine, two or more rotatingvalve openings may be provided in each case so that the outlet 28 isreleased several times and the turbine feed is correspondinglyinterrupted several times during each complete revolution of theturbine.

What is claimed is:
 1. A nozzle assembly for coupling with the outlet ofa rinsing device for personal hygiene, particularly for mouth washing,the assembly comprising a nozzle holder and means for interchangeablyattaching a nozzle to the holder, the nozzle holder comprised of twocoaxial parts screwed in relation to one another over a limited anglebetween two positions, one of which parts include a flow passage and theother including a closing member which cooperates with the flow passagein defining a shut-off valve and which in the one position blocks theflow passage and in the other position opens it, one of the two partsforming the nozzle holder including a cylindrical region at its outerperiphery, a plurality of diametrically opposite grooves in thecylindrical region, each of which has a groove section inclined to theaxis of the nozzle holder, which section at one end merges into anothergroove section extending at least approximately peripherally andorientated perpendicular to the axis of the nozzle holder, the otherpart of the nozzle holder comprising a number of projectionscorresponding to the number of grooves and being disposed therein, andone of the parts of the nozzle holder being an elongated hollow handleportion and comprising an internal pin situated inside the flow passage,the pin provided with a rounded head forming the closing member, and theother part comprising a bushing having an inner sleeve forming the flowpassage of the shut-off valve and adapted to receive a nozzle tube ofthe spray nozzle and an outer sleeve which is made integral with theinner sleeve and at the internal periphery of which there are formed theprojections disposed in the grooves.
 2. A nozzle assembly according toclaim 1, wherein the inner faces of the projections on the bushingextend inclined outwards in the backward direction in relation to theaxis of the nozzle holder.
 3. A nozzle assembly for coupling with theoutlet of a rinsing device for personal hygiene, particularly for mouthwasing, the assembly comprising a nozzle holder and means forinterchangeably attaching a nozzle to the holder, the nozzle holdercomprised of two coaxial parts screwed in relation to one another over alimited angle between two positions, one of which parts includes a flowpassage and the other including a closing member which cooperates withthis flow passage in defining a shut-off valve and which in the oneposition blocks the flow passage and in the other position opens it, oneof the two parts forming the nozzle holder including a cylindricalregion at its outer periphery, a plurality of diametrically oppositegrooves in the cylindrical region, each of which has a groove sectioninclined to the axis of the nozzle holder, which section at one endmerges into another groove section extending at least approximatelyperipherally and oriented perpendicular to the axis of the nozzleholder, the other part of the nozzle holder comprising a number ofprojections corresponding to the number of grooves and being disposedtherein, and one of the parts of the nozzle holder being an elongatedhollow handle portion, axial grooves being provided at the externalperiphery of the handle portion, said axial grooves having a smallerdepth than the groove sections and branching off therefrom, said axialgrooves extending as far as the front end of the handle portion, wherebyin assembling the two parts of the nozzle assembly, one part can bepushed onto the handle portion with engagement of the projections in theaxial grooves until said projections engage in said groove sections.